Plumes of neuronal activity propagate in three dimensions through the nuclear avian brain

Gabriël J L Beckers*, Jacqueline van der Meij, John A. Lesku, Niels C. Rattenborg

*Corresponding author for this work

Research output: Contribution to journalArticleAcademicpeer-review

Abstract

Background: In mammals, the slow-oscillations of neuronal membrane potentials (reflected in the electroencephalogram as high-amplitude, slow-waves), which occur during non-rapid eye movement sleep and anesthesia, propagate across the neocortex largely as two-dimensional traveling waves. However, it remains unknown if the traveling nature of slow-waves is unique to the laminar cytoarchitecture and associated computational properties of the neocortex.Results: We demonstrate that local field potential slow-waves and correlated multiunit activity propagate as complex three-dimensional plumes of neuronal activity through the avian brain, owing to its non-laminar, nuclear neuronal cytoarchitecture.Conclusions: The traveling nature of slow-waves is not dependent upon the laminar organization of the neocortex, and is unlikely to subserve functions unique to this pattern of neuronal organization. Finally, the three-dimensional geometry of propagating plumes may reflect computational properties not found in mammals that contributed to the evolution of nuclear neuronal organization and complex cognition in birds.

Original languageEnglish
Article number16
JournalBMC Biology
Volume12
Issue number16
DOIs
Publication statusPublished - 28 Feb 2014

Keywords

  • Bird
  • Cortex
  • Propagation
  • Sleep
  • Slow waves
  • Travelling

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